1. Agilex™ 5 Embedded Memory Overview
2. Agilex™ 5 Embedded Memory Architecture and Features
3. Agilex™ 5 Embedded Memory Design Considerations
4. Agilex™ 5 Embedded Memory IP References
5. Agilex™ 5 Embedded Memory Debugging
6. Embedded Memory User Guide: Agilex™ 5 FPGAs and SoCs Archives
7. Document Revision History for the Embedded Memory User Guide: Agilex™ 5 FPGAs and SoCs
2.1. Byte Enable in Agilex™ 5 Embedded Memory Blocks
2.2. Address Hold Support
2.3. Asynchronous Clear and Synchronous Clear
2.4. Memory Blocks Error Correction Code (ECC) Support
2.5. Agilex™ 5 Embedded Memory Clocking Modes
2.6. Agilex™ 5 Embedded Memory Configurations
2.7. Force-to-Zero
2.8. Coherent Read Memory
2.9. Freeze Logic
2.10. True Dual Port Dual Clock Emulator
2.11. Initial Value of Read and Write Address Registers
2.12. Automatic Timing/Power Optimization Feature in M20K Blocks
3.1. Consider the Memory Block Selection
3.2. Consider the Concurrent Write Behavior
3.3. Read-During-Write (RDW)
3.4. Consider Power-Up State and Memory Initialization
3.5. Reduce Power Consumption
3.6. Avoid Providing Non-Deterministic Input
3.7. Avoid Changing Clock Signals and Other Control Signals Simultaneously
3.8. Advanced Settings in Quartus® Prime Software for Memory
3.9. Consider the Memory Depth Setting
3.10. Consider Registering the Memory Output
4.1.4.1. RAM: 1-PORT FPGA IP Parameters
4.1.4.2. RAM: 2-PORT FPGA IP Parameters
4.1.4.3. RAM: 4-PORT FPGA IP Parameters
4.1.4.4. ROM: 1-PORT FPGA IP Parameters
4.1.4.5. ROM: 2-PORT FPGA IP Parameters
4.1.4.6. RAM and ROM Parameter Settings
4.1.4.7. Changing Parameter Settings Manually
4.1.4.8. RAM and ROM Interface Signals
4.2.5.1. FIFO Functional Timing Requirements
4.2.5.2. SCFIFO ALMOST_EMPTY Functional Timing
4.2.5.3. FIFO Output Status Flag and Latency
4.2.5.4. FIFO Metastability Protection and Related Options
4.2.5.5. FIFO Synchronous Clear and Asynchronous Clear Effect
4.2.5.6. SCFIFO and DCFIFO Show-Ahead Mode
4.2.5.7. Different Input and Output Width
4.2.5.8. DCFIFO Timing Constraint Setting
4.2.5.9. Gray-Code Counter Transfer at the Clock Domain Crossing
4.2.5.10. Guidelines for Embedded Memory ECC Feature
4.2.5.11. Reset Scheme
2.8.1. Forwarding Logic
With pipelining, you can use forwarding logic to perform data forwarding to reduce instruction cycles.
With coherent read feature and forwarding logic, you can coherently read out the data, perform operations (arithmetic or logical or both) on top of the data content, and write the data back to the same memory location within a single clock cycle.
Figure 13. Example Forwarding Logic with Simplified Coherent Read Memory Circuitry
Figure 14. Pipelining Waveform When Output of M20K Blocks is UnregisteredThis figure shows the waveform of the pipelining with the read enable (rden) signal is high.
Figure 15. Pipelining Waveform When Output of M20K Blocks is RegisteredThis figure shows the waveform of the pipelining with the write enable (wren) signal is high.
With the coherent read feature enabled and forwarding logic implemented, the output of M20K blocks can be either unregistered or registered. To match the latency of the coherency circuitry within the hardware boundary of the M20K blocks, you may need to manually add the additional pipeline registers on the wren and wraddress paths, which is described in the following table:
Output Register | Additional Pipeline Registers on wren and wraddress |
---|---|
Unregistered | 0 |
Registered | 1 |